Crystal structure of the natural anion-conducting channelrhodopsin GtACR1

Kim, Yoon Seok; Kato, Hideaki E.; Yamashita, Keitaro; Itô, Shota; Inoue, Kazuhide; Ramakrishnan, Charu; Fenno, Lief E.; Evans, K; Paggi, Joseph M.; Dror, Ron O.; Kandori, Hideki; Kobilka, Brian K.; Deisseroth, Karl

doi:10.1038/s41586-018-0511-6

Cited by 101 publications

(149 citation statements)

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“…15). Indeed, the CGs of the native cation channelrhodopsin-2 (CrChR2) 50 , chimeric cation channelrhodopsin (C1C2) 51 and also natural anion channelrhodopsin (GtACR1) 52,53 are composed of the S63-N258-E90, S102-N297-E129 and S43-N239-E68 triads ( Supplementary Fig. 15).…”

Section: Supplementary Textmentioning

confidence: 99%

Molecular mechanism of light-driven sodium pumping

Kovalev

Astashkin

Gushchin

et al. 2020

Preprint

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ABSTRACTMicrobial rhodopsins appeared to be the most abundant light-harvesting proteins on the Earth and are the major contributes to the solar energy captured in the sea. They possess highly diverse biological functions. Explosion of research on microbial rhodopsins led to breakthroughs in their applications, in particular, in neuroscience.An unexpected new discovery was a Na+-pumping KR2 rhodopsin from Krokinobacter eikastus, the first light-driven non-proton cation pump. A fundamental difference between proton and other cation pumps is that non-proton pumps cannot use tunneling or Grotthuss mechanism for the ion translocation and, therefore, Na+ pumping cannot be understood in the framework of classical proton pump, like bacteriorhodopsin. Extensive studies on the molecular mechanism of KR2 failed to reveal mechanism of pumping. The existing high-resolution structures relate only to the ground state of the protein and revealed no Na+ inside the protein, which is unusual for active ion transporters.KR2 is only known non proton cation transporter with demonstrated remarkable potential for optogenetic applications and, therefore, elucidation of the mechanism of cation transport is important. To understand conception of cation pumping we solved crystal structures of the functionally key O-intermediate state of physiologically relevant pentameric form of KR2 and its D116N and H30A key mutants at high resolution and performed additional functional studies.The structure of the O-state reveals a sodium ion near the retinal Schiff base coordinated by N112 and D116 residues of the characteristic (for the whole family) NDQ triad. The structural and functional data show that cation uptake and release are driven by a switching mechanism. Surprisely, Na+ pathway in KR2 is lined with the chain of polar pores/cavities, similarly to the channelrhodopsin-2. Using Parinello fast molecular dynamics approach we obtained a molecular movie of a probable ion release.Our data provides insight into the mechanism of a non-proton cation light-driven pumping, strongly suggest close relation of sodium pumps to channel rhodopsins and, we believe, expand the present knowledge of rhodopsin world. Certainly they might be used for engineering of cation pumps and ion channels for optogenetics.

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Section: Supplementary Textmentioning

confidence: 99%

Molecular mechanism of light-driven sodium pumping

Kovalev

Astashkin

Gushchin

et al. 2020

Preprint

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“…Microbial and animal rhodopsins (type-1 and 2 rhodopsins, respectively) comprise a superfamily of heptahelical (7-TM) transmembrane proteins covalently linked to a retinal chromophore (Ernst et al, 2014;Gushchin and Gordeliy, 2018). Type-1 rhodopsins are the most abundant light-harvesting proteins that have diverse functions, such as ion pumping, ion channeling, sensory and enzymatic activities (Gordeliy et al, 2002;Govorunova et al, 2015;Gushchin et al, 2013Gushchin et al, , 2015Kato et al, 2015;Kim et al, 2018;Mukherjee et al, 2019;Shevchenko et al, 2017;Volkov et al, 2017). The discovery, in 2000, of the light-driven pump proteorhodopsin (PR) in marine microbes triggered extensive search of metagenomes for light-activated proteins (Béjà et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

“…The study of microbial rhodopsins culminated in the development of optogenetics, the revolutionary method for controlling cell behavior in vivo using light-gated channels and light-driven pumps (Deisseroth, 2015). Currently, major efforts are being undertaken to identify rhodopsins with novel functions and properties that could be harnessed to enhance optogenetic applications (Berndt and Deisseroth, 2015;Berndt et al, 2014;Govorunova et al, 2015;Kato et al, 2018;Kim et al, 2018;Sineshchekov et al, 2017a).…”

Section: Introductionmentioning

confidence: 99%

Viral channelrhodopsins: calcium-dependent Na⁺/K⁺selective light-gated channels

Zabelskii

Alekseev

Kovalev

et al. 2020

Preprint

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Phytoplankton is the base of the marine food chain, oxygen, carbon cycle playing a global role in climate and ecology. Nucleocytoplasmic Large DNA Viruses regulating the dynamics of phytoplankton comprise genes of rhodopsins of two distinct families. We present a functionstructure characterization of two homologous proteins representatives of family 1 of viral rhodopsins, OLPVR1 and VirChR1. VirChR1 is a highly selective, Ca 2+ -dependent, Na + /K +conducting channel and, in contrast to known cation channelrhodopsins (ChRs), is impermeable to Ca 2+ ions. In human neuroblastoma cells, upon illumination, VirChR1 depolarizes the cell membrane to a level sufficient to fire neurons. It suggests its unique optogenetic potential. 1.4 Å resolution structure of OLPVR1 reveals their remarkable difference from the known channelrhodopsins and a unique ion-conducting pathway. The data suggest that viral channelrhodopsins mediate phototaxis of algae enhancing the host anabolic processes to support virus reproduction, and therefore, their key role in global phytoplankton dynamics.

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“…Anion channelrhodopsins from the cryptophyte alga Guillardia theta ( Gt ACRs) are the most potent optogenetic inhibitors of neuronal firing and regulators of animal behavior currently available (Govorunova et al 2015; Mahn et al 2018; Messier et al 2018; Mohammad et al 2017; Wilson et al 2018). Recently we and others have obtained high-resolution X-ray structures of the dark (closed) state of G. theta anion channelrhodopsin 1 ( Gt ACR1) (Kim et al 2018; Li et al 2019). In contrast to available structures of cation channelrhodopsins (CCRs) from green algae (Kato et al 2012; Oda et al 2018; Volkov et al 2017), Gt ACR1 exhibits a narrow continuous intramolecular tunnel formed by helices 1-3 and 7 that connects the cytoplasmic and extracellular aqueous phases and presumably expands upon illumination to pass anions (Li et al 2019).…”

Section: Introductionmentioning

confidence: 99%

“…However, no open channel structure is yet available, and many questions regarding its architecture remain unanswered. In particular, a possible role of the second extracellular vestibule (Kim et al 2018) in anion conductance has not so far been tested experimentally. Also, the functional significance of the many structural differences between ACRs and CCRs is not yet clear.…”

Section: Introductionmentioning

confidence: 99%